RADIO COMMUNICATION SYSTEM, BASE STATION APPARATUS, RADIO TERMINAL AND COMMUNICATION CONTROL METHOD
A radio communication system includes a first base station (11) that manages a first cell (110), a second base station (12) that manages a second cell (120), and a radio terminal (2). The radio terminal (2) supports dual connectivity involving a bearer split in which a first network bearer between the radio terminal (2) and a core network (3) is split over the first base station (11) and the second base station (12). The first base station (11) receives, from the second base station (12), bearer split status information about communication of the first network bearer in the second base station (12), and performs control of an access stratum related to the first network bearer. It is thus possible to contribute, for example, to an improvement in control of an access stratum when dual connectivity involving a bearer split is performed.
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This application is a Continuation of U.S. application Ser. No. 17/356,943 filed Jun. 24, 2021, which is a Continuation of U.S. application Ser. No. 15/969,443 filed May 2, 2018, issued as U.S. Pat. No. 11,089,588 on Aug. 10, 2021, which is a Continuation of U.S. application Ser. No. 15/028,915 filed Apr. 12, 2016, issued as U.S. Pat. No. 10,721,728 on Jul. 21, 2020 which is a National Stage of International Application No. PCT/JP2014/002423 filed May 7, 2014 (claiming priority based on Japanese Patent Application No. 2013-227473 filed Oct. 31, 2013), the contents all of which are incorporated herein by reference in their entirety.
TECHNICAL FIELDThis application relates to a radio communication system in which base stations communicate with the same radio terminal in their respective cells.
BACKGROUND ARTTo improve deterioration in communication quality due to the recent rapid increase in mobile traffic and to achieve higher-speed communication, 3GPP Long Term Evolution (LTE) specifies a carrier aggregation (CA) function to allow a radio base station (eNode B (eNB)) and a radio terminal (User Equipment (UE)) to communicate with each other using a plurality of cells. The cells which can be used by the UE in the CA are limited to cells of one eNB (i.e., cells that are served or managed by the eNB). The cells used by the UE in the CA are classified into a primary cell (PCell) that is already used as a serving cell when the CA is started and a secondary cell(s) (SCell(s)) that is used additionally or subordinately. In the PCell, Non Access Stratum (NAS) mobility information (NAS mobility information) and security information (security input) is sent and received during radio connection (re)-establishment (RRC Connection Establishment, RRC Connection Re-establishment) (see Section 7.5 in Non-Patent Literature 1).
In the CA, SCell configuration information transmitted from the eNB to the UE includes SCell radio resource configuration information common to UEs (RadioResourceConfigCommonSCell) and SCell radio resource configuration information dedicated to a specific UE (RadioResourceConfigDedicatedSCell). The latter information mainly indicates a dedicated configuration (PhysicalConfigDedicated) for a physical layer. When cells (carriers) having different transmission timings (Timing Advance: TA) are aggregated in an uplink, configuration information (MAC-MainConfigSCell) about a Medium Access Control (MAC) sublayer is also transmitted from the eNB to the UE. However, the configuration information about the MAC sublayer includes only an STAG-Id, which is an index of TA Group (TAG) representing a set of cells included in the same TA (see Section 5.3.10.4 in Non-Patent Literature 2). The other configurations for the MAC sublayer in the SCell are the same as those in the PCell.
One of the ongoing study items in the LTE standardization related mainly to a Heterogeneous Network (HetNet) environment is dual connectivity in which the UE performs communication using a plurality of cells of a plurality of eNBs (see Non Patent-Literature 3). Dual connectivity is a process to allow an UE to perform communication simultaneously using both radio resources (i.e., cells or carriers) provided (or managed) by a main base station (master base station, Master eNB (MeNB)) and a sub base station (secondary base station, Secondary eNB (SeNB)). Dual connectivity enables inter-eNB CA in which the UE aggregates a plurality of cells managed by different eNBs. Since the UE aggregates radio resources managed by different nodes, dual connectivity is also called “inter-node radio resource aggregation”. The MeNB is connected to the SeNB through an inter-base-station interface called Xn. The MeNB maintains, for the UE in dual connectivity, the connection (S1-MME) to a mobility management apparatus (Mobility Management Entity (MME)) in a core network (Evolved Packet Core (EPC)). Accordingly, the MeNB can be called a mobility management point (or mobility anchor) of the UE. For example, the MeNB is a Macro eNB, and the SeNB is a Pico eNB or Low Power Node (LPN).
Further, in dual connectivity, a bearer split for splitting a network bearer (EPS bearer) over the MeNB and the SeNB has been studied. The term “network bearer (EPS Bearer)” used in this specification means a virtual connection that is configured between a UE and an endpoint (i.e., Packet Data Network Gateway (P-GW)) in a core network (EPC) for each service provided to the UE. In an alternative of the bearer split, for example, both a radio bearer (RB) in a cell of the MeNB and a radio bearer in a cell of the SeNB are mapped to one network bearer. The radio bearer (RB) described herein refers mainly to a data radio bearer (DRB). The bearer split will contribute to a further improvement in user throughput.
CITATION LIST Non Patent Literature
- [Non-Patent Literature 1] 3GPP TS 36.300 V11.5.0 (2013-March), “3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA) and Evolved Universal Terrestrial Radio Access Network (E-UTRAN); Overall description; Stage 2 (Release 11)”, March, 2013
- [Non-Patent Literature 2] 3GPP TS 36.331 V11.4.0 (2013-June), “3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Radio Resource Control (RRC); Protocol specification (Release 11)”, June, 2013
- [Non-Patent Literature 3] 3GPP TR 36.842 V0.2.0 (2013-May), “3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Study on Small Cell Enhancements for E-UTRA and E-UTRAN Higher layer aspects (Release 12)”, May, 2013
In the LTE, an UE generates an uplink (UL) Medium Access Control Protocol Data Unit (MAC PDU) to be transmitted using available resources (Uplink Grant) allocated from an eNB. One MAC PDU is also called a transport block. In the generation of an UL MAC PDU, logical channels configured in the UE are multiplexed on one MAC PDU. At this time, it is necessary to guarantee the QoS of each EPS bearer configured in the uplink. Accordingly, the UE generates an UL MAC PDU in accordance with a Logical Channel Prioritization (LCP) procedure. In the Logical Channel Prioritization (LCP) procedure, a priority and a Prioritized Bit Rate (PBR) are given to each logical channel. The PBR is a bit rate which is provided to one logical channel before allocating any resource to a logical channel having a lower priority. The PBR is configured by the eNB for each logical channel. In the LCP procedure, first, all logical channels are guaranteed to be allocated resources corresponding to respective PBRs in descending order of their priorities. Next, if there are still any available resources left after all logical channels have been served up to their PBR, the remaining resources are allocated to the logical channels in a descending order of priorities of the logical channels until there is no data of logical channels, or until the allocated resources are used up.
However, in dual connectivity involving a bearer split, it is considered that the MeNB and the SeNB each independently perform Radio Resource Management (RRM). Accordingly, there is a possibility that the MeNB and the SeNB each independently perform the above-mentioned LCP procedure, which may lead to an unfairness between resources (i.e., effective bit rate) allocated to a logical channel (or EPS bearer, radio bearer) which is not subjected to a bearer split and is transmitted only in the PCell and resources allocated to a logical channel (or EPS bearer, radio bearer) which is subjected to a bearer split and is transmitted in the PCell and the SCell. In other words, the balance of resource allocation between a logical channel which is not subjected to a bearer split and a logical channel which is subjected to a bearer split may be lost, and consequently, the LCP procedure may not function as intended.
In the case of performing dual connectivity involving a bearer split, there is a possibility that expected performance cannot be obtained not only in the generation of MAC PDUs (i.e., the LCP procedure) described above, but also in other Layer 1/Layer 2 control in an access stratum. For example, in uplink transmission power control (PC), there is a possibility that the distribution of transmission power between the uplink transmission in the PCell and the uplink transmission in the SCell may not be performed as intended. Further, in the case of performing dual connectivity involving a bearer split, there is a possibility that expected performance cannot be obtained not only in the uplink Layer 1/Layer 2 control, but also in the downlink Layer 1/Layer 2 control. It is also possible that expected performance cannot be obtained in control of layer 3 of the Access stratum (i.e., Radio Resource Control (RRC)) in the uplink or the downlink or both.
Accordingly, one object to be achieved by embodiments disclosed in the specification is to contribute to an improvement in control of an access stratum when dual connectivity involving a bearer split is performed. Other objects and novel features will become apparent from the following description and the accompanying drawings.
Solution to ProblemIn an embodiment, a radio communication system includes a first base station that manages a first cell, a second base station that manages a second cell, and a radio terminal. The radio terminal supports dual connectivity involving a bearer split in which a first network bearer between the radio terminal and a core network is split over the first base station and the second base station. The first base station is configured to receive, from the second base station, bearer split status information about communication of the first network bearer in the second base station, and to perform control of an access stratum related to the first network bearer.
In an embodiment, a base station apparatus includes a communication control unit configured to control dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over the base station apparatus and a neighbor base station. The communication control unit is configured to receive, from the neighbor base station, bearer split status information about communication of the first network bearer in the neighbor base station, and to perform control of an access stratum related to the first network bearer.
In an embodiment, a base station apparatus includes a communication control unit configured to control dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over the base station apparatus and a neighbor base station. The communication control unit is configured to transmit, to the neighbor base station, bearer split status information about communication of the first network bearer in the base station apparatus. The bearer split status information triggers the neighbor base station to perform control of an access stratum related to the first network bearer.
In an embodiment, a radio terminal is used in the radio communication system described above and includes a communication control unit configured to control dual connectivity involving a bearer split in which the first network bearer is split over first and second base stations. The communication control unit is configured to perform control of an access stratum related to the first network bearer based on an instruction from the first base station.
In an embodiment, a control method includes: (a) starting, by a first base station, communication of dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over the first base station and a second base station; and (b) receiving, by the first base station from the second base station, bearer split status information about communication of the first network bearer in the second base station, and performing, by the first base station, control of an access stratum related to the first network bearer.
In an embodiment, a control method includes: (a) starting, by a second base station, communication of dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over a first base station and the second base station; and (b) transmitting, to the first base station, bearer split status information about communication of the first network bearer in the second base station. The bearer split status information triggers the first base station to perform control of an access stratum related to the first network bearer.
In an embodiment, a program includes instructions (software codes) for causing a computer to perform the above-described method when the program is loaded into the computer.
Advantageous Effects of InventionAccording to the embodiments described above, it is possible to contribute to an improvement in control of an access stratum when dual connectivity involving a bearer split is performed.
Specific embodiments will hereinafter be described in detail with reference to the drawings. The same or corresponding elements are denoted by the same reference symbols throughout the drawings, and repeated descriptions thereof are omitted as appropriate for clarity of the explanation.
First EmbodimentFirst, with regard to some embodiments including this exemplary embodiment, several examples of dual connectivity (e.g., inter-node radio resource aggregation) involving a bearer split are described.
In the alternatives shown in
Like in the alternative shown in
The following description is based on an assumption that a cell of the MeNB 11 can be called a PCell and a cell of the SeNB 12 can be called an SCell from the viewpoint of the conventional Carrier Aggregation (CA). However, the scope of this embodiment is not limited to this. For example, when the radio terminal (UE) performs the CA (Intra-SeNB CA) on a plurality of cells of the SeNB 12 (i.e., at least a plurality of downlink Component Carriers (CCs)) during dual connectivity, one of the cells of the SeNB 12 subjected to the CA may be defined as a PCell or a pseudo PCell which functions similarly to a PCell. The pseudo PCell can also be called an Anchor cell, a Master cell, a Control cell, or the like. In the CA of the cells of the SeNB 12, the former cell (the PCell of the SeNB 12) has a role similar to that of the PCell in the conventional CA. In the PCell of the SeNB 12, for example, the eNB (SeNB) carries out SCell configuration or SCell activation/deactivation for the CA, and the UE carries out Radio Link Monitoring (RLM)/Radio Link Failure (RLF) detection. Further, the UE may perform, for example, transmission of L1/L2 control information (e.g., CQI, CSI, HARQ feedback, Scheduling Request) in an uplink control channel (PUCCH), transmission of (a preamble of) a Contention-based Random Access Channel (RACH), and reception of a response (Random Access Response (RAR)) to the RACH Preamble. The latter cell (the Pseudo PCell of the SeNB 12) has a role as a cell having a PCell function regarding the control of a User Plane (UP) in the conventional CA. In the Pseudo PCell of the SeNB 12, the UE may perform, for example, transmission of L1/L2 control information in the uplink control channel (PUCCH), transmission of (a preamble of) a Contention-based RACH, and reception of a response (RAR) to the RACH Preamble. Furthermore, in the UE, the cells of the MeNB 11 and the cells of the SeNB 12 need not necessarily have a hierarchical relationship (PCell and SCell) or a master-slave relationship.
The user plane protocol stack for dual connectivity involving a bearer split is not limited to the alternatives shown in
The user plane protocol stack in the uplink direction of LTE Layer 2 related to dual connectivity involving a bearer split is similar to that in the downlink direction described above.
The E-UTRAN 1 and the UE 2 according to this embodiment support dual connectivity involving a bearer split. Specifically, while using the cell 110 of the eNB (i.e., MeNB) 11 as a primary cell (PCell), the UE 2 can use the cell 120 of the eNB (i.e., SeNB) 12 as a secondary cell (SCell). The UE 2 can receive and/or transmit data of one EPS bearer subjected to a bearer split through the PCell 110 and the SCell 120.
In order to improve the Layer 1/Layer 2 control of an access stratum in the case of performing dual connectivity involving a bearer split, the MeNB 11 and the SeNB 12 according to this embodiment carry out a control procedure or signalling as described below. The SeNB 12 is configured to transmit, to the MeNB 11, bearer split status information about communication in the SeNB 12 (i.e., SCell 120) of the EPS bearer to be subjected to a bearer split (hereinafter referred to as a split EPS bearer). The MeNB 11 is configured to perform control of the access stratum related to the split EPS bearer in response to receiving the bearer split status information from the SeNB 12.
The bearer split status information may include, for example, at least one of communication status information, radio resource control information, and admission control information.
The communication status information indicates a communication status of the split EPS bearer in the SeNB 12 (i.e., SCell 120). The communication status of the split EPS bearer in the SeNB 12, which is indicated by the communication status information and sent to the MeNB 11 from the SeNB 12, may be a communication status in Layer 1 or Layer 2 of the SCell 120. More specifically, the communication status of the split EPS bearer in the SeNB 12 may include at least one of the following items (1) to (6):
-
- (1) Statistics of throughput;
- (2) Statistics of allocated radio resources;
- (3) Statistics of packet losses;
- (4) Statistics of power headroom;
- (5) Information about retransmission control in the Radio Link Control (RLC) sublayer; and
- (6) Information about packet discarding in the Radio Link Control (RLC) sublayer.
The statistics of throughput may be, for example, at least one of an average value, a minimum value, and a maximum value of a data rate (e.g., transmission rate or data rate of PDCP SDU, PDCP PDU, RLC PDU, or MAC PDU (i.e., Transport Block)) of the UE 2 in the SeNB 12. The statistics of allocated radio resources may be, for example, at least one of an average value, a minimum value, and a maximum value of radio resources allocated to the UE 2 in the SeNB 12. In this case, the radio resources may be, for example, resource blocks. When the SeNB 12 transmits data of the split EPS bearer to the UE 2 by using a plurality of cells, the statistics of throughput and the statistics of radio resources may be a value in each of the plurality of cells, or the total value of the plurality of cells.
The statistics of packet losses may be, for example, the number or ratio of discarded packets in a radio interface (LTE-Uu interface) between the SeNB 12 and the UE 2, or in an inter-base-station interface (Xn interface) between the MeNB 11 and the SeNB 12. In this case, the packets may be, for example, PDCP SDUs, PDCP PDUs, RLC PDUs, or MAC PDUs (i.e., Transport Blocks). The statistics of packet losses may be statistics observed not for the Xn interface, but for an X2 interface or an S1 interface.
The statistics of uplink power headroom indicate, for example, an average value of power headroom of the UE 2 for the SCell 120 (in a predetermined period). The power headroom indicates a difference (i.e., surplus transmission power) between the uplink maximum transmission power of the UE 2 and the transmission power of a Physical Uplink Shared channel (PUSCH) in the present subframe. The UE 2 reports the power headroom for the SCell 120 to the SeNB 12. The UE 2 may report the power headroom for the PCell 110 and the power headroom for the SCell 120 to the SeNB 12.
The information about retransmission control in the RLC sublayer may indicate a NACK ratio of Automatic Repeat Request (ARQ) for RLC PDUs (i.e., logical channel) of the split EPS bearer (i.e., a ratio of NACKs with respect to the total of ACKs and NACKs), the number of retransmissions in the ARQ, or a frequency of occurrence of retransmission in the ARQ.
The information about packet discarding in the RLC sublayer may indicate the rate or number of discarded RLC SDUs of the split EPS bearer, or the data amount of discarded RLC SDUs. Packet discarding in the RLC sublayer (i.e., discarding of RLC SDUs) may be executed in response to an instruction from the PDCP sublayer of the MeNB 11. Alternatively, the RLC sublayer of the SeNB 12 may independently determine whether to perform packet discarding.
The communication status information transmitted from the SeNB 12 to the MeNB 11 may indicate, for example, a communication status monitored for each split EPS bearer, monitored for each ratio bearer mapped to the split EPS bearer, monitored for each SCell 120, or monitored for each SeNB 12. The communication status monitored for each SCell 120 may be obtained by observation of each SCell 120 and each radio terminal (UE) which performs a bearer split, or may be obtained by observation of each SCell 120 and a plurality of radio terminals which perform a bearer split in the SeNB 12. The same is true of the communication status monitored for each SeNB 12.
Next, the control of the access stratum performed by the MeNB 11 is described. The control of the access stratum may be, for example, a Layer 1 control, a Layer 2 control, a Layer 3 control, or any combination thereof. Several examples of the Layer 1/Layer 2 control of the access stratum are given below. Note that, the Layer 1/Layer 2 control of the access stratum may be a Layer 3 (RRC) control or signalling regarding functions in Layer 1 (PHY)/Layer 2 (MAC, RLC, and PDCP). For example, the MeNB 11 may perform at least one of the following controls (a) to (c) in response to receiving from the SeNB 12 the communication status of the split EPS bearer in the SeNB 12.
(a) Control for Generation of Uplink (UL) MAC PDUsEven during execution of the bearer split, the UE 2 should generate MAC PDUs in consideration of an EPS bearer QoS (QoS class identifier (QCI), a guaranteed bit rate (GBR), an aggregate maximum bit rate (AMBR), etc.) for each of all EPS bearers including a split EPS bearer and a non-split EPS bearer. Accordingly, if the uplink LCP procedure does not function as intended due to, for example, the excess uplink throughput of the split EPS bearer in the SCell 120, the MeNB 11 may adjust an uplink Prioritized Bit Rate (PBR) or Bucket Size Duration (BSD) or both of them, which are applied to the split EPS bearer or the non-split EPS bearer or both of them, so that the LCP procedure functions as intended. For example, when the throughput of the split EPS bearer in the SCell 120 is excessive, the MeNB 11 may decrease the uplink PBR applied to the split EPS bearer in the PCell 110 and may increase the uplink PBR applied to the non-split EPS bearer in the PCell 110. In this case, the PBR can also be called a prioritized resource amount. For example, the RRC layer in the MeNB 11 may determine the PBR applied to the split EPS bearer and the PBR applied to the non-split EPS bearer, and may notify the UE 2 of the determined PBR values by RRC signalling. The PBR applied to the split EPS bearer in the PCell 110 may be the same as or different from that in the SCell 120. Further, the MeNB 11 may determine the BSD for each of the split EPS bearer and the non-split EPS bearer, and may notify the UE 2 of the obtained BSD values. The BSD of the split EPS bearer in the PCell 110 may be the same as or different from that in the SCell 120. Non-Patent Literature 2 (3GPP TS 36.331) specifies parameters regarding the LCP including the PBR and the BSD (see FIG. 4). The parameters shown in
The MeNB 11 may adjust the transmission power of the UE 2 to achieve intended distribution of transmission power between uplink transmission in the PCell 110 and uplink transmission in the SCell 120. For example, in response to determining, based on the communication status information received from the SeNB 12, that the power headroom of the UE 2 in the PCell 110 is less than the power headroom of the UE 2 in the SCell 120 by more than a predetermined amount, the MeNB 11 may adjust a parameter(s) used for a formula for calculating PCMAX so as to increase the configured maximum transmission power PCMAX, PCELL in the PCell 110 of the UE 2 and to decrease the configured maximum transmission power PCMAX, SCELL in the SCell 120 of the UE 2. The formula for calculating PCMAX is specified in 3GPP TS 36.301. Specifically, the MeNB 11 may adjust the maximum transmission power (i.e., transmit power limit) PEMAX, PCELL, which is allowed for the UE 2 in the PCell 110, or the maximum transmission power PEMAX, SCELL, which is allowed for the UE 2 in the SCell 120, or both of them. Non-Patent Literature 2 (3GPP TS 36.331) specifies parameters regarding the UL transmission power control (see
The MeNB 11 may perform control regarding the downlink similar to the above-described control for generation of uplink MAC PDUs. Specifically, in response to determining, based on the communication status information received from the SeNB 12, that the downlink LCP procedure does not function as intended, the MeNB 11 may adjust the downlink PBR for the split EPS bearer or the downlink PBR for the non-split EPS bearer or both of them, so that the LCP procedure functions as intended. For example, when the downlink throughput of the split EPS bearer in the SCell 120 is excessive, the MeNB 11 may decrease the downlink PBR applied to the split EPS bearer in the PCell 110 and may increase the downlink PBR applied to the non-split EPS bearer in the PCell 110. In this case, the PBR can also be called a prioritized resource amount.
The above description concentrates on an example in which the SeNB 12 reports to the MeNB 11 the communication status regarding the split EPS bearer in the SeNB 12 (SCell 120) and the MeNB 11 performs the Layer 1/Layer 2 control of the access stratum. However, it should be noted that the roles of the MeNB 11 and the SeNB 12 are interchangeable. Specifically, the MeNB 11 may report to the SeNB 12 the communication status related to the split EPS bearer in the MeNB 11 (PCell 110). The SeNB 12 may perform the Layer 1/Layer 2 control of the access stratum related to the split EPS bearer in response to receiving the communication status information from the MeNB 11 (PCell 110).
Next, a specific example of the control procedure according to this embodiment is described.
In step S13, the MeNB 11 sends a bearer split status request to the SeNB 12. In step S14, in response to receiving the bearer split status request, the SeNB 12 sends a bearer split status response to the MeNB 11. The bearer split status response includes the bearer split status information. Note that steps S13 and S14 are only illustrative. For example, the SeNB 12 may send the bearer split status information periodically or non-periodically, regardless of the request from the MeNB 11.
In step S15, the MeNB 11 performs control (e.g., Layer 1/Layer 2 control) of the access stratum related to the split EPS bearer based on the bearer split status information received from the SeNB 12. As described above, the MeNB 11 may perform control for generation of uplink MAC PDUs (e.g., adjustment of PBR), uplink transmission power control (e.g., adjustment of PEMAX), or control for generation of downlink MAC PDUs (e.g., adjustment of PBR). In the example shown in
In
As can be seen from the above description, according to this embodiment, the MeNB 11 (or SeNB 12) is configured to receive the bearer split status information from the SeNB 12 (or MeNB 11) and to perform control of the access stratum. In some implementations, the bearer split status information includes communication status information indicating communication status of the split EPS bearer in the SeNB 12. In this case, according to this embodiment, the Layer 1/Layer 2 control of the access stratum is performed based on the communication status information between the MeNB 11 and the SeNB 12. Thus, in this embodiment, when dual connectivity involving a bearer split is performed, unfairness between communication of the split EPS bearer and that of the non-split EPS bearer can be corrected, and generation of MAC PDUs, transmission power control, and the like can be optimized so that they can be performed as intended.
Second EmbodimentIn this embodiment, a specific example of the Layer 1/Layer 2 control for uplink transmission, which is included in the control of the access stratum based on sharing of the bearer split status information between the MeNB 11 and the SeNB 12 according to the first embodiment, is described. A configuration example of a radio communication system according to this embodiment is similar to that shown in
In step S22, the MeNB 11 transmits a control message for controlling uplink communication of an EPS bearer(s) that is configured in the UE 2 and includes a split EPS bearer. In the example shown in
In step S23, the UE 2 performs uplink communication of a split EPS bearer with the MeNB 11 and the SeNB 12 in accordance with the control by the MeNB 11 in step S22. Step S23 may include uplink communication of a non-split EPS bearer in the PCell 110.
The processing of steps S24 and S25 may be performed in the same manner as the processing of steps S13 and S14 shown in
In step S26, the MeNB 11 performs uplink Layer 1/Layer 2 control for the split EPS bearer based on the bearer split status information received from the SeNB 12. In the example shown in
In step S27, the UE 2 performs uplink communication of the split EPS bearer with the MeNB 11 and the SeNB 12 in accordance with the control by the MeNB 11 in step S26. Step S26 may include uplink communication of the non-split EPS bearer in the PCell 110.
In
Next, a specific example of the control for generation of uplink MAC PDUs is described with reference to
To overcome the undesirable situation shown in
The uplink Layer 1/Layer 2 control performed in this embodiment may be uplink transmission power control. In this case, the SeNB 12 may report, to the MeNB 11, information about the power headroom of the UE 2 in the SCell 120 as the communication status information. The information about the power headroom may be statistics, such as an average value of the power headroom, or other information indicating the size of the power headroom. The MeNB 11 may adjust the transmission power of the UE 2 by taking into account both the power headroom of the UE 2 in the PCell 110 and the power headroom of the UE 2 in the SCell 120. For example, as described above, the MeNB 11 may adjust one or both of PEMAX,PCELL and PEMAX,SCELL when it is determined that the power headroom of the UE 2 in the PCell 110 is less than the power headroom of the UE 2 in the SCell 120 by more than a predetermined amount. Specifically, the MeNB 11 may increase PEMAX,PCELL and decrease PEMAX,SCELL. PEMAX,PCELL represents the maximum transmission power (i.e., transmit power limit) allowed for the UE 2 in the PCell 110, and PEMAX,SCELL represents the maximum transmission power allowed for the UE 2 in the SCell 120. PEMAX, PCELL and PEMAX,SCELL are used to determine the configured maximum transmission power PCMAX,PCELL in the PCell 110 and PCMAX,SCELL in the SCell 120. PCMAX,PCELL and PCMAX,SCELL may be determined according to the calculation formulas (PCMAX,C) specified in 3GPP TS 36.301.
Also in the example of the uplink transmission power control, the roles of the MeNB 11 and the SeNB 12 are interchangeable. Specifically, the MeNB 11 may report, to the SeNB 12, the information about the power headroom of the UE 2 in the PCell 110. Further, the SeNB 12 may adjust the uplink maximum transmission power of the UE 2 in one or both of the PCell 110 and the SCell 120 in consideration of the power headroom of the UE 2 in the PCell 110.
Third EmbodimentIn this embodiment, a specific example of the Layer 1/Layer 2 control for downlink transmission, which is included in the control of the access stratum based on sharing of the bearer split status information between the MeNB 11 and the SeNB 12 according to the first embodiment, is described. A configuration example of a radio communication system according to this embodiment is similar to that shown in
In step S32, the MeNB 11 and the SeNB 12 perform downlink communication of a split EPS bearer with the UE 2. Step S32 may include downlink communication of a non-split EPS bearer in the PCell 110.
The processing of steps S33 and S34 may be performed in the same manner as the processing of steps S13 and S14 shown in
Specifically, in step S33, the MeNB 11 sends a bearer split status request to the SeNB 12. In step S34, in response to receiving the bearer split status request, the SeNB 12 sends a bearer split status response including the bearer split status information to the MeNB 11. Instead of performing steps S33 and S34, the SeNB 12 may send the bearer split status information periodically or non-periodically, regardless of the request from the MeNB 11.
The bearer split status information sent in step S34 may indicate information relating to the downlink communication of the UE 2 in the SCell 120, including communication status information, radio resource control information, or admission control information, or any combination thereof. The communication status information may indicate statistics (e.g., average value) of radio resources (i.e., the number of resource blocks) allocated to the UE 2 in the SCell 120.
The communication status information may indicate statistics (e.g., average value) of the throughput (e.g., transmission rate or data rate of PDCP SDUs, PDCP PDUs, RLC PDUs, or MAC PDUs (Transport Blocks)) of the UE 2 in the SCell 120. The communication status information may also indicate a packet loss rate, information about retransmission control in the RLC sublayer, information about packet discarding in the RLC sublayer, and the like.
The radio resource control information may be information about radio resources used in the SCell 120 for data (service) from the split EPS bearer. More specifically, the radio resource control information in the SeNB 12 may include at least one of the following information items (1) to (3):
-
- (1) Information about an increase or decrease in radio resources;
- (2) Information about available radio resources; and
- (3) Information about surplus radio resources.
The information about an increase or decrease in radio resources may indicate, for example, that the number of radio resources can be increased (or a request to increase the number of radio resources can be made), or the number of radio resources can be reduced (or a request to reduce the number of radio resources can be made), according to the use status or the like of radio resources used for a bearer split (i.e., split EPB bearer) in the SeNB 12.
The information about available radio resources may indicate, for example, radio resources which can be allocated to the data (service) of the split EPS bearer in the SeNB 12.
The information about surplus radio resources may indicate, for example, radio resources which are not used in the SeNB 12 (i.e., radio resources which can be used for data transmission or the like). Examples of the radio resources may include the number of resource blocks, the number of packets (PDCP PDUs, PDCP SDUs, RLC PDUs, RLC SDUs, MAC PDUs (TBs), etc.), and the number of cells (i.e., the number of downlink and/or uplink carriers).
The admission control information may be information relating to admission executed in the SeNB 12 on data (service) of the split EPS bearer (i.e., information about whether a bearer split can be accepted). More specifically, the admission control information in the SeNB 12 may include at least one of the following information items (1) to (5):
-
- (1) Information about whether or not to admit a new bearer split;
- (2) Information about a wait time until a new bearer split is acceptable;
- (3) Information about a wait time until a request for a new bearer split is made;
- (4) Information about estimated (expected) throughput (data rate); and
- (5) Information about an estimated (expected) amount of radio resources to be allocated.
The information about whether or not to admit a new bearer split may indicate, for example, whether a new bearer split is allowed in the SeNB 12, or the number of new bearer splits that can be allowed in the SeNB 12 (i.e., the number of EPS bearers transmitted by radio bearers (RBs) in a cell of the SeNB 12 in the case of a bearer split).
The information about a wait time until a new bearer split is acceptable may indicate, for example, an expected minimum wait time until a bearer split is acceptable in the SeNB 12, or a wait time until a bearer split is acceptable.
The information about a wait time until a request for a new bearer split is made may indicate, for example, a prohibited time during which sending (by the MeNB 11) a request for a bearer split to the SeNB 12, i.e., sending a request for transmitting data (service) of the split EPS bearer in a cell of the SeNB 12, is prohibited.
The information about an estimated (expected) data rate (throughput) may indicate, for example, an estimated (expected) data rate (e.g., throughput) in the SeNB 12, or a level of a data rate (e.g., throughput) (e.g., an index value indicating one of several predetermined levels of data rates).
The information about an estimated (expected) amount of radio resources to be allocated may indicate, for example, an estimated (expected) amount of radio resources to be allocated in the SeNB 12, or a level of an amount of radio resources (e.g., an index value indicating one of several predetermined levels of the amount of radio resources). Examples of the radio resources may include the number of resource blocks, the number of packets (PDCP PDUs, PDCP SDUs, RLC PDUs, RLC SDUs, MAC PDUs (TBs), etc.), and the number of cells (i.e., the number of downlink and/or uplink carriers).
In step S35, the MeNB 11 may perform the downlink Layer 1/Layer 2 control for the split EPS bearer based on the bearer split status information received from the SeNB 12. As shown in
In the downlink Layer 1/Layer 2 control in step S35, the MeNB 11 may update a parameter(s) related to the LCP procedure applied to generation of downlink MAC PDUs (e.g., PBR). For example, when the average value of radio resources allocated to the UE 2 in the SCell 120 is equal to or greater than a predetermined value, the MeNB 11 may decrease the downlink PBR (i.e., prioritized resource amount) for the logical channel of the split EPS bearer of the UE 2 in the PCell 110. Further, the MeNB 11 may increase the downlink PBR for the non-split EPS bearer of the UE 2 in the PCell 110. Accordingly, when dual connectivity involving a bearer split is performed, the unfairness between downlink communication of the split EPS bearer and downlink communication of the non-split EPS bearer can be corrected, and thus generation of MAC PDUs, transmission power control, and the like can be optimized so that they can be performed as intended.
In step S36, the MeNB 11 and the SeNB 12 perform downlink communication of the split EPS bearer with the UE 2 in accordance with the control by the MeNB 11 in step S35. Step S36 may include downlink communication of a non-split EPS bearer in the PCell 110.
In
In this embodiment, modified examples of the first to third embodiments are described. A configuration example of a radio communication system according to this embodiment is similar to that shown in
For example, the SeNB 12 may request the MeNB 11 to increase, decrease, or update the amount of downlink data (e.g., PDCP PDU) on the split EPS bearer that is split in the MeNB 11 and is transmitted to the SeNB 12.
In another alternative, the SeNB 12 may request the MeNB 11 to adjust the maximum transmission power allowed for the UE 2 in the PCell 110 or the SCell 120.
In still another alternative, the SeNB 12 may request the MeNB 11 to adjust the Prioritized Bit Rate (PBR) which is applied to the logical channel of the split EPS bearer when the UE 2 generates the uplink MAC PDUs for the PCell 110 or the SCell 120.
In yet another alternative, the SeNB 12 may request the MeNB 11 to stop the dual connectivity involving a bearer split related to the UE 2.
These requests from the SeNB 12 to the MeNB 11 may be sent periodically or non-periodically (by event-triggered) according to the load of the SeNB 12 (SCell 120), or the characteristics of a physical channel (e.g., Physical Downlink Shared Channel (PDSCH)), a transport channel (e.g., Downlink Shared channel (DL-SCH)), or a logical channel (e.g., Dedicated Traffic channel (DTCH)).
Next, configuration examples of the MeNB 11, the SeNB 12, and the UE 2 according to the first to fourth embodiments described above are described.
A transmission data processing unit 112 receives user data addressed to the UE 2 from the communication unit 114, and performs error correction coding, rate matching, interleaving, or the like, to thereby generate a transport channel. Further, the transmission data processing unit 112 adds control information to a data sequence of the transport channel, to thereby generate a transmission symbol sequence. The radio communication unit 111 generates a downlink signal by performing processing including carrier wave modulation based on the transmission symbol sequence, frequency conversion, and signal amplification, and transmits the generated downlink signal to the UE 2. The transmission data processing unit 112 receives control data to be transmitted to the UE 2 from the communication control unit 115, and transmits the received control data to the UE 2 via the radio communication unit 111.
The communication control unit 115 controls dual connectivity involving a bearer split. In some implementations, the communication control unit 115 may generate configuration information and control information necessary for dual connectivity involving a bearer split, and may transmit the generated information to the SeNB 12 and the UE 2. Further, the communication control unit 115 may perform control of the access stratum in response to receiving from the SeNB 12 the bearer split status information (e.g., communication status information) related to the split EPS bearer. The communication control unit 115 may send to the SeNB 12 the bearer split status information (e.g., communication status information) related to the split EPS bearer to trigger the control of the access stratum in the SeNB 12.
A communication control unit 125 of the SeNB 12 controls dual connectivity involving a bearer split. The communication control unit 125 may send to the MeNB 11 the bearer split status information (e.g., communication status information) related to the split EPS bearer to trigger the control of the access stratum in the MeNB 11. Further, the communication control unit 125 may perform control of the access stratum in response to receiving from the MeNB 11 the bearer split status information (e.g., communication status information) related to the split EPS bearer.
A communication control unit 25 of the UE 2 controls dual connectivity involving a bearer split. The communication control unit 25 performs control of the access stratum relating to the split EPS bearer based on an instruction from the MeNB 11 or the SeNB 12.
OTHER EMBODIMENTSThe communication control processes in the MeNB 11, the SeNB 12, and the UE 2 in association with dual connectivity involving a bearer split as described in the first to fourth embodiments may be implemented by a semiconductor processing device including an Application Specific Integrated Circuit (ASIC). These processes may be implemented by causing a computer system including at least one processor (e.g., a microprocessor, a Micro Processing Unit (MPU), or a Digital Signal Processor (DSP)) to execute a program. Specifically, one or more programs including instructions for causing the computer system to perform algorithms described above with reference to sequence diagrams and the like may be created, and the program(s) may be supplied to a computer.
The program(s) can be stored and provided to a computer using any type of non-transitory computer readable media. Non-transitory computer readable media include any type of tangible storage media. Examples of non-transitory computer readable media include magnetic storage media (such as flexible disks, magnetic tapes, hard disk drives, etc.), optical magnetic storage media (e.g. magneto-optical disks), Compact Disc Read Only Memory (CD-ROM), CD-R, CD-R/W, and semiconductor memories (such as mask ROM, Programmable ROM (PROM), Erasable PROM (EPROM), flash ROM, Random Access Memory (RAM), etc.). The program(s) may be provided to a computer using any type of transitory computer readable media. Examples of transitory computer readable media include electric signals, optical signals, and electromagnetic waves. Transitory computer readable media can provide the program to a computer via a wired communication line, such as electric wires and optical fibers, or a wireless communication line.
In the first to fourth embodiments, the LTE system is mainly described. However, as described above, these embodiments may be applied to radio communication systems other than the LTE system, such as a 3GPP UMTS, a 3GPP2 CDMA2000 system (1×RTT, HRPD), a GSM/GPRS system, or a WiMAX system.
Further, the above embodiments are only illustrative of the application of the technical idea obtained by the present inventor. That is, the technical idea is not limited only to the above embodiments and can be modified in various ways as a matter of course.
REFERENCE SIGNS LIST
-
- 1 EVOLVED UTRAN (E-UTRAN)
- 2 USER EQUIPMENT (UE)
- 3 EVOLVED PACKET CORE (EPC)
- 11 MASTER eNodeB (MeNB)
- 12 SECONDARY eNodeB (SeNB)
- 25 COMMUNICATION CONTROL UNIT
- 110 PRIMARY CELL (PCell)
- 120 SECONDARY CELL (SCell)
- 115 COMMUNICATION CONTROL UNIT
- 125 COMMUNICATION CONTROL UNIT
Claims
1. A base station apparatus comprising:
- a memory; and
- at least one hardware processer coupled to the memory and configured to execute modules comprising a communication controller configured to control dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over the base station apparatus and a neighbor base station,
- wherein the communication controller is configured to receive, from the neighbor base station, bearer split status information about communication of the first network bearer in the neighbor base station, and to perform control of an access stratum related to the first network bearer.
2. The base station apparatus according to claim 1, wherein the control of the access stratum includes control of a Logical Channel Prioritization (LCP) procedure for generating, in the radio terminal, at least one of a first Medium Access Control Protocol Data Unit (MAC PDU) for uplink transmission in a first cell managed by the base station apparatus and a second MAC PDU for uplink transmission in a second cell managed by the neighbor base station.
3. The base station apparatus according to claim 2, wherein the control of the LCP procedure includes at least one of adjusting a Prioritized Bit Rate (PBR) applied to an uplink logical channel of the first network bearer and adjusting a PBR applied to an uplink logical channel of a second network bearer transmitted via the first cell without being subjected to the bearer split.
4. The base station apparatus according to claim 1, wherein the control of the access stratum includes uplink transmission power control of at least one of a first cell managed by the base station apparatus and a second cell managed by the neighbor base station.
5. The base station apparatus according to claim 4, wherein the uplink transmission power control includes at least one of adjusting maximum transmission power allowed for the radio terminal in the first cell and adjusting maximum transmission power allowed for the radio terminal in the second cell.
6. The base station apparatus according to claim 1, wherein the control of the access stratum includes control of downlink scheduling in at least one of a first cell managed by the base station apparatus and a second cell managed by the neighbor base station.
7. The base station apparatus according to claim 6, wherein the control of the downlink scheduling includes at least one of adjusting a Prioritized Bit Rate (PBR) applied to a downlink logical channel of the first network bearer and adjusting a PBR applied to a downlink logical channel of a second network bearer transmitted via the first cell without being subjected to the bearer split.
8. The base station apparatus according to claim 1, wherein the bearer split status information includes at least one of communication status information, radio resource control information, and admission control information.
9. The base station apparatus according to claim 8, wherein
- the bearer split status information includes the communication status information indicating a communication status of the first network bearer in the neighbor base station, and
- the communication status information indicates at least one of statistics of throughput, statistics of allocated radio resources, statistics of packet losses, statistics of power headroom, and information about retransmission control in a Radio Link Control (RLC) sublayer.
10. The base station apparatus according to claim 8, wherein
- the bearer split status information includes the radio resource control information relating to radio resources used in a cell managed by the neighbor base station for the first network bearer, and
- the radio resource control information indicates at least one of information about an increase or decrease in radio resources, information about available radio resources, and information about surplus radio resources.
11. The base station apparatus according to claim 8, wherein
- the bearer split status information includes the admission control information relating to admission, executed in a cell managed by the neighbor base station, on data of the first network bearer, and
- the admission control information indicates at least one of information about whether or not to admit a new bearer split, information about a wait time until a new bearer split is acceptable, information about a wait time until a request for a new bearer split is made, information about expected throughput, and information about an expected amount of radio resources to be allocated.
12. A base station apparatus comprising:
- a memory; and
- at least one hardware processer coupled to the memory and configured to execute modules comprising a communication controller configured to control dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over the base station apparatus and a neighbor base station, wherein
- the communication controller is configured to send, to the neighbor base station, bearer split status information about communication of the first network bearer in the base station apparatus, and
- the bearer split status information triggers the neighbor base station to perform control of an access stratum related to the first network bearer.
13. The base station apparatus according to claim 12, wherein the control of the access stratum includes control of a Logical Channel Prioritization (LCP) procedure for generating, in the radio terminal, at least one of a first Medium Access Control Protocol Data Unit (MAC PDU) for uplink transmission in a first cell managed by the neighbor base station and a second MAC PDU for uplink transmission in a second cell managed by the base station apparatus.
14. The base station apparatus according to claim 12, wherein the control of the access stratum includes uplink transmission power control of at least one of a first cell managed by the neighbor base station and a second sell managed by the base station apparatus.
15. The base station apparatus according to claim 12, wherein the control of the access stratum includes control of downlink scheduling in at least one of a first cell managed by the neighbor base station and a second cell managed by the base station apparatus.
16. The base station apparatus according to claim 12, wherein the bearer split status information includes at least one of communication status information, radio resource control information, and admission control information.
17. The base station apparatus according to claim 16, wherein
- the bearer split status information includes the communication status information indicating a communication status of the first network bearer in the base station apparatus, and
- the communication status information indicates at least one of statistics of throughput, statistics of allocated radio resources, statistics of packet losses, statistics of power headroom, and information about retransmission control in a Radio Link Control (RLC) sublayer.
18. The base station apparatus according to claim 16, wherein
- the bearer split status information includes the radio resource control information relating to radio resources used in a cell managed by the base station apparatus for the first network bearer, and
- the radio resource control information indicates at least one of information about an increase or decrease in radio resources, information about available radio resources, and information about surplus radio resources.
19. The base station apparatus according to claim 16, wherein
- the bearer split status information includes the admission control information relating to admission, executed in a cell managed by the base station apparatus, on data of the first network bearer, and
- the admission control information indicates at least one of information about whether or not to admit a new bearer split, information about a wait time until a new bearer split is acceptable, information about a wait time until a request for a new bearer split is made, information about expected throughput, and information about an expected amount of radio resources to be allocated.
20. A communication control method comprising:
- starting, by a first base station, communication of dual connectivity involving a bearer split in which a first network bearer between a radio terminal and a core network is split over the first base station and a second base station;
- receiving, by the first base station from the second base station, bearer split status information about communication of the first network bearer in the second base station, and performing, by the first base station, control of an access stratum related to the first network bearer.
Type: Application
Filed: Jul 3, 2023
Publication Date: Nov 2, 2023
Applicant: NEC Corporation (Tokyo)
Inventors: Hisashi FUTAKI (Tokyo), Hiroto SUGAHARA (Tokyo)
Application Number: 18/217,901